Electrical measuring device



Dec. 11,1945. Z. ER 2,390,811

ELECTRI CAL MEASURING DEVICE Filed 001;. 22, 1 942 2 Sheets-Sheet 1 la .50 I50 2Q lab INVENTOR Fm6r0JeJ/%/z/hyen ZZM ATTORNEY WITNESSES:

Dec. 11, 1945; J zm E 2,390,811

ELECTRICAL MEASURING DEvIcE 7 Filed Oct. 22, 1942 2 Shets-Sheet 2 4 IOW le .5: lie

. INVENTOR fimbroaefPefz/nyer.

ATTgRjgEY peres.

Patented-Dec. 11, 1945 ELECTRICAL MEASURING imvrca Ambrose J. Petzinger, Paterson, N. 1,, assignor to Westinghouse Electric Corporation, East Pittsburgh, Pa., a corporation of Pennsylvania Application October 22, 1942, Serial No. 462,968

16 Claims.

This invention relates to electrical measurin devices, and it has particular relation to measuring devices for measuring a function of a pluraliw of variable quantities and adjustable to cover a plurality of ranges of one or the variable quantities.

In certain classes of electrical measuring devices, provisions must be made for measurin a plurality of ranges of a variable quantity. If a separate measuring device is provided for each of the ranges of the variable quantitythe construction of the measuring devices is substantially simplified. This simplification is attained, however, at the sacrifice of an increase in the number of measuring devices required For this reason,

it is desirable to provide a single measuring device which is adjustable for covering a plurality of ranges of the variable quantity. The problem may be understood more clearly by a consideration of watthour meters, and particularly of standard watthour meters.

For several years, the standard rated capacities of watthour meters have been 5, 15 and 50 am- These watthour meters are designed for operation at 120 and 240 volts. Some watthour meters are designed for higher voltages, such as 480 volts. In addition to the present standard capacities, a number of watthour meters are in service which have other rated current capacities.

In order to test or check watthour meters for accuracy, it is the practice to provide standard watthour meters which are sometimes referred to as rotating standards or more briefly as standards. Such standards are adjustable to cover a plurality of ranges of watthour meters. For'example, standard watthour meters are available for'measuring current ranges represented by rated full load currents of i, and 15 amperes. Other standard watthour meters are available for measuring ranges represented byrated full load currents of 1, 5, 10, 25 and 50 amperes. Such standard watthour meters are also provided with adjustments covering two operating voltages, such as 120 and 240 volts.

ln eonstructing standafd watthour meters, it hasbeen the practice to employ thesame number of ampere turns per current pole for each of the rated full load currents covered by the adjustments of the standard watthour meter. For example, in a standard watthour meter having ranges represented by rated full load currents of 1, 5, 10, 25 and 50 amperes, the-cu'rrent windings may be adjusted to provide 50 ampere-turns per current Dole when energize by each of, the rated full load currents.

To date, no commercial standard watthour meter is available for measuring the standard watthour ureter capacities represented by full load currents of 5, 15 and 50 amperes.- This is require'the provision 'of 150 ampere-turns per current pole in such a standard watthour'aneter at the rated full load current in each range: The provision of such a standard watthour '"meter having 150 ampere-turns per current pole-is impracticable.

In accordance with the invention, advantage is taken 0! the fact that a watthour meter measures a function of two variable quantities; namely,

voltage and current. To provide a standardwatthour meter capable of measuring current ranges represented by full load currents mi 1, 5, 15, and 50 amperes, the current windings of the standard watthour meter are designed to provide fewer ampereturns for certain oi the rated full load currents than for other of the rated full load currents- For example, in: the standard watthour meter having the five ranges referred to, the windings may be arranged to provide ampere-turns when energized by the rated full load currents of 1, 5 and 15 amperesin the first three ranges. The current windings also may be arranged to provide ampere-turns when energized by rated full load currents of 25 and 50 amperes in the last two ranges.

In order to assure similar rotation of the standard watthour meter armature in each ofits ranges, the voltage magnetic flux of the standard watthour meter is adjusted to compensate for the difference in ampere-turns produced in the various ranges. For example, the number of turns of the voltage winding of the standard watthour meter may be adjusted to provide a larger voltage magnetic flux in the 1, 5 and 15 amperecapacity ranges ofthe standard watthour meter than in the 25 and50 ampere-capacity ranges. Alternatively, transformer means may be provided for increasing the voltage applied to the voltagewinding in the 1, 5 and 15 ampere-capacity ranges or the standard watthour meter sumcientiy to provide similar operation of the standard watthour meter in all of its ranges.

A further problem is presented by the practice of testing watthour meters at full load and at light load. The light load conventionally employed for testing a watthour meter is one-tenth of the rated full load of the watthour meter. Hereis somewhat difllcult to obtain accurate readings under light load conditions.

In accordance with a. further aspect of the invention, a standard watthour meter is provided which provides operation similar to its rated full load operation when energized by currents correspondingto light load energization of the watthour meter to 'be tested. For the purpose for the reason that conventional practice would of discussion, let it be assumed that a standard turns 'per current pole.

meter testing system embodying the invention;

and

Figs. 2, 3 and 4 are schematic views showing modifications of portions of the system of Fig. 1. Referring to the drawings-Fig. 1 shows an electrical syste-m embodying the invention. This system includes a standard watthour meter having a magnetic core 60. The magnetic core provides a voltage pole 62 and current poles 84 and 88 which are spaced to define an air gap within which a conductive rotating element or armature 88 is mounted for rotation. As well understood in the art, when a shifting magnetic field is produced-in the air gap, a torque is applied to the armature 68 which operates to rotate the armature. In accordance with conventional practice, a permanent magnet (not shown) is provided for damping rotation of the armature 88 and a register (not shown) is provided for indicating the number of rotations of the armature 68.

For providing a shifting magnetic fleld in the air gap containing the armature 58, the voltage pole I52 is provided with a pair of voltage windings and I2 and the current poles are provided with a plurality of windings Iw to Him. As well understood in the art, when these windings are energized suitably in accordance with the voltage and current of an electrical circuit, the armature 88 rotates at a rate dependent on the energy flowing in the electrical circuit.

The windings Iw to 920 each have oneturn' wound around each of the current poles 64 and 88. The windings low have the equivalent of 45 turns wound around each of the current poles 64 and B6. The turns around the respective current poles are wound in opposite direct ons so that when the cun'entsin the i'bms direct a magnetic flux downwardly in the current pole 84. they also serve to direct a magnetic flux upwardly in the current pole 66 as viewed in Fig. 1. Conveniently remaining end of the winding low and to the terminal lb. The remaining conductor 84 supplying current to the standard watthour meter is connected to a terminal No on the control unit 8|! and to the terminal 90.

Connections are provided on the drum controller l6 for establishing proper connections between the terminals thereof. For example, a tie conductor 86 has its ends connected to a contact segment on each of the control units 18 and 80 for-establishing a connection between the terminals lb and lie when the drum controller 16 is in its first position I a. A tie conductor 88 has its ends connected to segments on the control units 18 and 80 for establishing a connection between the terminal 9b and the terminal 80 in the first three positions Ia, 5a and lie of the drum controller. A tie conductor 89 has its ends connected to contact segments on the control units 18 and BI! for establishing a connection between the term nal 8b and the terminal 'lc in the first four positions, Ia, 511,151: and 25a'oi the drum controller. A tie conductor 9Il.has its ends connected to contact segments on the control units for establishing a connection between the terminal 3b and the terminal 20 in the first three positions la, 5a and I5a of the drum controller. A tie conductor 92 has its ends connected to se ments on the control units 18 and 80 for establishing a connection between the terminals zb and I0 in the first four positions Ia, 5a, Wu and Illw may be provided by winding one or more additional turns on each of the current poles such as 46 turns per current'pole; A resistor 14 then is connected in shunt with the windings lllw and is proportioned to reduce the effectiveness of the winding low to the equivalent of exactly In order to control the connections of the windings on the current DOles 64 and 66. a drum controller 78 is provided having a plurality of positions la. 5a, I5a, 25a and 50a. Th s drum controller is shown in developed form in Fig. 1. In each of its positions. the drum controller is designed to group the windings Iw to Illw for ener ization in accordance with a different capacity of watthour meters to be te ted. As a specific example. it is assumed that the positions of the drum controller are designed to energirev the current windings oi the standard watthour meter to test watthour-meters with currents of 1 ampere, 5 amneres, l5 amneres. 25 amperes and 50 amperes. To provide the necessary grouping of windings. the dr m controller I6 is divided into two control units 18 and 8B.

The current windings of the standard watthour windings Iw to 910 are connected, respectively.

to the terminals Ic to 8c of the. control unit 80. One of the conductors 82 supplying current to the standard watthour meteris connected to the v 25a. of the drum contrgller. A tie conductor 94 has its ends connected to contact segments on the control'units lli and 88 for establishing a connection between the terminals 5b and 4c in the first three positions In, 5a and I5a of the drum controller. A tie conductor 96 has its ends connected to contact segments on the control units' for establishing a. connection between the terminals 679 and 5c in the first four positions I a, 5:1, i511 and 25a of the drum controller. A tie conductor 98 has its ends connected to contact segments on the control units for establishing a connection between the terminals 1b and 6c in the first two positions Ia-and 5a of the drum controller. A tie conductor I00 ha its ends connected to contact segments on the control units fo establishing a connection between the terminals 4b and 3c in the positions 5a and 25a of the drum controller.

The control unit 78 also carries a segment I I32 which engages the terminal Ib in the position 512 of the drum controller. In the position. lie; of the drum controller the contact segment I02 en-v gages the terminals Ib, 4b and 1b. The terminals lb, lb, 5b and 3b are engaged by the con tact segment I02 in the/position 25a of the drum controller 16. All of the terminals Ib to 9b inelusive, are engaged by the contact segment I02 in the position 5011 of the drum controller 16.

In a somewhat similarmanner, the control unit 80 includes a contact segment I04 which engages the terminal in the position 5a of the drum controller. The contact segment I04 engages the terminals 9c, 30 and Bo in the position I5a of the conductors 82 and 84. Consequently. if one ampere flows through theconductors 82 and 84 a are previded an lareuf I imfllewindingslw-iwareinsefles aemsstbeeunduaursflandll. Thisthat whmfiamperesflowinthellandll, p l'etumsperpole meeun'enlpolesilandii.

In the position Ila of the drum euntmller Ii, m

current flowing through the 82 and flpa thewindinsslmlmandiwin parallel. Thissameeurrentthmthmugh zmiwandlwmparalleland thmushtheimimandswin amnel.

Inotherwmdscurrentmustflowthree S B Of-"' 1111;: E men: as

,whenlSam throughtheflandu,45ampere pflpoleare houldtlzeilbemitspusb 82and8lthmughthe 3 may ings. Farthiswhenfiamfluwin theeonduetors'llandllwampa'eturnsper cmentpolearedeveloped. 7 Whenthe-Fisimim illmallofthe lw-Swarein confluetors l2 and 84 divida these 9 -windingsendproducesfioamperemspercurrentpole.

new i; it were desired to rovidethe sagne n of ampere turns tor 40 each posifionofthedrmn eontmnenitwtmldhe .ntowurkon'e. basis at mamperetums. Byemployingtwootfiamperewrnsmd ampere turns, M w a mterlal saving in the equired ampere turns is at In order to provide voltage a 11-. re the voltage polefil one ormore are provided. specific example mum in Fig. 1, the two vultag 1. and 11 orlseriesuiaeraflmatmvdtsand 00 ,paralleriatmwolis. Tothe Tll andfleitherineerimmmpulllel. asuitableswitehfllimayte Theoperaflon'oIflfisswih-hwiflbeindehfl in'thesmme 4w; were providediqr-mdr drum controller '16-,theutfl1e armature 'ilwmflflnotbethezsamelor otthe eurrentbymtedineaehdtheio 5 poaitionsofthe drnmz. 'Tlflshfor turnspermrrent'ypole'whereasintln cfor teeth:

4 amen amperetumspereljrrm tpoleatthereepeeflve rsbedeurrmts. 'l'oeompensfle torthisdifl'erotflaeenrrentwlndings, thevoltasepolefltsmtebly Befm'lng tuner-1t mu observed thatthe mm: 1101: I2 Bprovlded roltazellland Ill. Inthe 'liaandllautthedrumlqoneut thevolhgelllandllliseon meerlesrrlflzeachofflxemainvolhs dqm aback Mme piiedvnitlgekredueed. Bysuibm the mum; voltage win v ings lllmd lllflhem-voltngeml w mm flux man"! be to the ziaandllmdthedrmnaethem flonuftheermnmeinthe lm iuend iiaetthedrmfliwlxenthecurreut autumn-eats in the nrkm'nnges. I

the auxflhry voltage Ill lm wbetoflmmamwltage lland'libymeaneotaeepamtely epmtedswlmswimhmeansisprovidedisupentedby-mtaflmotthedmm u. Tummtheammconmne: theruvithacamlflwhlehrotafiesin'theoftheamw lllawhm theliisaematedmthe parallel. entlyjflamperes flowingmthe 35.

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duetorlllhthe'fll. Ammndcir- "eultmw he conductor I26 theeunhetfll,thela,a

through 't oposim 0' mlmthemeuummdmm,

ductor Ill and the the contacts Ill and Ill 01 the switch Ill, a conductor Ill, and the voltage winding N to the conductor I2l. Consequently, the voltage windings 1l and 12 alone are connected in parallel across the conductors I2l and I2l.

As previously explained, the switch Ill controls thejparallel and series connections oi" the voltage In the position of the switch Ill illustrated in Fla. 1. the voltage windings are connectedin parallel for operation at a predetermined i'roltage such as 120 volts. In this position of the switch, a rotatable cam Illa has a raised portion engaging a resilient finger 'Illb and a depressed portion engaging a resilient finsex- I llc. These resilient fingers have biases urgingthe fingers towards the axis Illd about which the cam rotates. When the cam Illa is rotated 180 to bring its raised portion into engagement with the finger Illc and its depressed portion into engagement with the finger Illb, the contacts Ill and. Ill are separated respectively from the contacts Ill and Ill. In addition, a contact Il2 carried hy the resilient finger Illc moves irom' engagement with a fixed contact Ill into engagement with a fixed contact Ill. Such operation of "the switch Ill connects the voltage windings ll and 12 in series through a circuit which ma i be traced .irom the conductor I2l,

through the contact I2l, a conductor Ill. the conductor I32, the voltage winding", the conductor I'll,'the contacts Ill and Ill, the con-1 conductor I2l.

When the drum controller 1l moves into one of its positions Ila or lla, the fingers Ill and Ill are moved into engagement with the contacts I22 and I2l. Such movement of the fingers results in the connection oi the auxiliary voltage windings Ill and III in series with the main voltage windings and 12.. Such connection may be traced ,irom the conductor I 26 through the conductor I ll, the auxiliary voltage winding III, a conductor Ill, a conductor "2, the contact I 22,'the conductor Ill, the contacts Ill and Ill, the conductor Ill, and the voltage winding III to the conductor I28. Consequently, the auxiliary voltagewinding I ll and the main voltage winding 10 are connected in series across the conductors I2land I28. V

A second energizing circuit may be traced from the c0nductorj26 through the conductor Ill, the

contact Ill, aco'nductor Ill, the auxiliary voltage winding Ill, a, conductor Ill, the contact I24,

voltage winding II to the rating oi 120 volts and current windings I12 which are assumed to have a current rating oi 5 amperes. In order to test the watthour meter, a source of voltage I" having the desired voltage rating and an adjustable loadrepresented by an adjustable resistor I" are provided.

The voltage winding of the meter M is connected across the source Ill for energization in accordance with the voltage thereof. In an analogous manner, the conductors I26 and I2l are connected for energization in accordance with the voltage of the source Ill. If the voltage windings 1l and 12 are designed for energization in parallel at 120 volts and in series at 240 volts. th witch Ill is left in the position illustrated in Fig. 1. This means that the voltage windings N and 12 are connected in parallel for energization in accordance with the voltage of the source Ill.

Since the watthour meter M is assumed to have a rated current capacity of 5 amperes, the drum controller Il is moved to its positions la. In this position 0! the drum controller, the current windings Iw-lw are connected in series with the current windings I12 between the source I" and the load I'll. The load I'll is then adjusted to provide a current now oi 5' amperes. The rotation or the rotating element or armature oi the watthour meter M to be tested and the rotation of the arma-' ture of the standard watthour. meter then may be compared in the conventional manner.

It the voltage winding III were designed for energiaation at 240 volts, it would have been necessary to rotate the cam Illa of the switch Ill to bring its raised portion into engagement with the finger Illc. This would have. connected at voltage windings N and 12 in series for energization in accordance with the voltage of the source I1l.'

' Had the current windings I12 been designed for a rated current capacity oi 50 aniperes, it would have been necessary to operate the drum controller 1.l into the position lla. In this position or the drum controller allof the windings Iw-lw are connected in parallel and the parallel group is connected in series with the current windings I12 oi the watthour meter lid to be tested for energization in accordance with current supplied by the source I".

At the same time, operation of the drum con! troller H to its position lla brings the raised 7 portions of the cam '2 into engagement with the conductorflllll, the conductor I32, the main voltage winding 12, the conductor Ill, the contacts I36 and I'll; and the conductor Ill to the conductor I28. f Consequently, the auxiliary voltage winding Ill and the main voltage winding 12 are connected' in series across the conductors I2l-and m. f

With the controller ll in one of its positions 25a or soc; should the cam Illa oi the switch Ill be actuated to bring its raised portion into engagementwith. the finger Illc, it would be found that the auxiliary voltage windings Ill and Ill and themain voltage windings M and 12 all would be., connected in series across the conductors I26 and I2l. It is believed that these connections maybe readily traced on Fig. 1.

It is believed that the operationot the standard watthour meter illustrated in F 1 is app ent from the f re oin description thereof. Let it be assumed that a watthour meter M is to be tested. This watthour meter has a voltage winding in which be assumed to have a voltage the fingers Ill and Ill. As previously explained,

such actuation oi the'iingers Ill and Ill connects the auxiliary voltage windings Ill and Ill respectively in series with the main voltage windings 10 and 12. The resulting decrease in voltage magnetic flux produced In the voltage Dole l2 compensates for the increase in ampere turns per current pole i'rom ll in the position la oi the drum controller to ll in theposition We of the drum controller when rated current flows through the current windings. It will be understood also that the load Ill is adjusted to produce the required current flow of 50 amperes through the watthour meters in order to make a full load test thereof. Tests of the watthour meter M may be conducted at other loads, such as at light loads, by proper adjustment of the load I'll. v

In Fig. 1, proper adjustment of the voltage magnetic flux in the voltage pole l2 is efiected by proper connections or the auxiliary voltage windings Ill and Ill. Ii desired, these auxiliary voltage windings may be omitted and adjustment or the voltage magnetic flux may be eflected by 6 asaopu stood that the cam II2b is onnected for opera-- tion by movement of the'drum controller II in a manner similar to the connection or the cam As shown in Fig. 2, a pair oi resilient fingers -II8and I88 are associated with the com "2!) and are urged towards the center thereon The cam II2b is provided with'raised portions which,

engage the resilient fingers I18 and I88 when the drum controller 18 is in its positions 28a and 58a. The depressed portions of the cam iI2b engage the fingers I18 and I88 in the positions In. is and lid of the drum controller 18.

In the position of the cam II2b illustrated in Fig. 2, energization of the voltage windings l8 and I2 is efiected through a transformer I82 which conveniently may be of the auto-transformer type. The primary section or the autotransiormer I82 is connected for energization' across the conductors I28 and I28 through a fixed contact I84 and a movable contact I88 which is actuated in accordance with movement or the movable finger I88. The secondary section oi the auto-transformer I82 is connected between the conductor I28 and a movable contact I88 which also is associated with the finger I88 for, 3

movement therewith.

In the position of the parts illustrated in Fig. 2,.

the movable contact I88 engages a fixed contact I89. Thisconnects the windings l8 and 82 across the secondary section .of the auto-transformer I82 for energizatlon at a voltage higher than that across the conductors I28 and I28.

The switch I88 again controls the series or parallel connection of the voltage windings l8 and I2. Because of the omission or the auxiliary windings I88 and iii, the construction or the switch I88 is somewhat simpler than that or the switch I880: Fig. 1. It is'believed that the parallel and series connections tor-the two positions oi the switch I88 maybe readily traced in Fig. 2.

When the drum controller l8 is actuated to move the raised portions or the cam I121: into engagement with the fingers I18 and I88, the contacts I88 and I88 are separated respectively, from the fixed contacts I88 and I88. Such separation of the contacts removes the auto-transformer I82 from service and connects the voltage windings I8 and 12 directly across the conductors I28 and I28. As previously pointed out, the cam II2b is proportioned to establish. this direct connection oi the voltage windings III and 12 only for the positions 25a and 88a oi the drum controller.

It will be understood that the auto-transformer I82 increases the voltage applied to the voltage windings I and I2 in the positions In, in and Ila oi the drum controller by an amount sufilcient to compensate for the reduced number oi ampere turns available in the current windings in these positions or the drum controller. For example, if the voltage of the conductors I28 and I28 is 120 volts, the secondary section oi the. auto-transformer I82 may be designed to produce an output voltage of about 133.3. volts. when so proportioned, corresponding currents in each'otthe rotationotthearmatureoithcstandardwafl- Itisstandard-practiceintheartto test watthourmeters at full load and at light load.- For 6 theiuilloadtestrated fullloadcurrentissupplied to the watthour meter whereas for the lightload test one-tenth of rated full load current conventionally is applied to the watthour meter. To facilitate tests o! this character, the system of Fig. 1 may be modified as illustrated in Fig. '3.

Referring to Fig. 3, a drum controller lib is provided which corresponds to the drum controller 18 oi Fig. 1. This drum controller lib has 5 positions, 85d, Lid, id, lid and 88d for con trolling the connections of the windin s ho to 820 or the standard watthour meter. Instead of the single winding I 810. the current poles of the standard watthour meter are provided with two windings I2w and Ilw. These windings are designed- 20 to provide respectively 88 and 88 effective turns.

Conveniently the current windings I21 and Iiw may have a larger number of turns, such as 3| and 8| respectively. shunting resistors I2" and I2 then may be connected thereacross and propor- 25 tioned to make the windings l2w and i810 equivalent to exactly 88 audio eiiective'turns.

The drum controller 181) is divided into a control unit 18b and a control unit 88b which are associated with the ends oi the various windings.

'30 For example, the control unit 18b has terminals iii to 8b to which are connected, respectively, one end of each of the. windings Iw to 9w. In a similar manner, the control unit 80 has terminals Ic to 80 to which are connected respectively, one

5 end of each of the windings ho to 8w. The wind,-

ngs I210 and I 8w each. have an and connected to a common terminal I2". The'r'emaining end oi the winding Iiw is connected to a terminal III; which is associated with control unit 181:. One

40 of the conductors 82 which supplies current to the windings is connected to the remaining end of the winding I210 and to the terminal ID.

The other conductor 88 for supplying current to the windin s is connected to the terminal 80 and is to two additional terminals lie and I8c on the control unit 88b. l

For establishing proper connections of the varioils 'windlngs', a tie conductor I88 has its ends connected to contact segments respectively on the control units 18b and 88b for connecting the terminals I21) and lie in the position Lid of the drum controller 18b. A tie conductor I82 has contact segments connected to its ends for establishing a connection between theterminals I21:

and lie in the 05d position ofthe drum con- .troiler 18b. In an analogous manner, tie conductors I88, "8,198, 200, "land 2 are provided each having contact segments at its ends for establishing connections between the terminal o Oh and the'terminal 8c, between the terminal 8b and the terminal 'Ic, between the terminal to and the terminal 2c, between the terminal 2b and the terminal Ic, between the terminal ib andthe terminal 8c, and between the terminal 8b 5 and the terminal in the positions lid; Lid,

' 8d and lid or the drum controller lib. A. tie conductor 288 has contact segments for establishing a connection between the terminal lb and theterminal 8c in the first three positions 0.5a,

7o Lid and Mo: the drum controller. A tie con" ductor 288 has contact segments establishing aconnection between the terminals lb and 8c in the position id oi the drum controller 18!). In addition, the control unit 18b has a contact.

ranges or the drumcontroller I8 produce'thesame 7s segment 2") for engaging the contact lb in the position d of the drum controller; for em:- ing the terminals lb, 4b and lb in the podtion lid of the drum controller; and for eng in all of the terminals lb to 9b in the position 58d 01 the "drum controller. In a similar manner, the control unit 80b has a contact segment 2 I! for engaging the terminal 8c in the position 5d. of the drum controller; for engaging the terminals 80, 8c, and 6c in the position lid of the drum controller; and for engaging all of the terminals lc to 8c in th position 50d of the drum controller.

When the drum controller 185 is in its position 8.5d. the windings Ilw and l8w are connected in series across the conductors 82 and 8|. (louse quently, when these conductors supply .5.ot an ampere to the windings, 45 ampere turns per current pole are produced in the standard watthour meter.

When the drum controller 185 is in the position l.5d, the winding the is connected across th conductors 82 and 84; Therefore, when these conductors supply 1.5 amperes to thestandard watthour meter, '45 ampere turns per current pole are produced.

It the drum controller 18b is. in lts position Id,-

all of the windings ho to 810 inclusive, are conis placed in the appropriate position Md, Ltd or M. These positions assure full load operation of the standard watthour meter despite the fact that the associated watthour meter to be tesed is energized a one-tenth its rated full load. Suchoperation of the standard watthour meter facilitates greatly the determination of its operation under the conditions of the test. In other words,

revolution of the test meter at light load or for case nested in series across the conductors 82-84.. Therefore, a flow of 5 amperes in the conductors 82 and 84 represents 45 ampere turns per current pole in the standard watthour meter.

In the position lid of the drum controller, current supplied by the conductors 82 and 84 flows .flrst through the windings lw, 410 and In: in parallel, then through the windings I, I and 8 in paralll. and finally thro g -the windings 3, 8 and 8 in parallel. For this reason, a flow 01 15 amperes in the conductors 82 and 84 again produces 45 ampere turns per current pole in the standard watthour meter.

Finally, in the position 60a of the drum controller, alloi the windings Ito-8w are connected in parallel across the conductors 82 and 84.

Therefore, a flow of' 50 amperes through the conductors 82 and 84 results in the application of 50 ampere turns per current pole to the standard watthour meter.

in the same manner. However, the raised portions of the cam 20 are proportioned to engage the associated contact fingers Ill and 5 only in the position 50d of the associated drum controller 16b.

The operation of the modification illustrated in Fig. 3 will be understood from the discussion of 'Fig. 1. II it is desired to conduct a full-load'test of a 5 ampere, 15 ampere or 50 ampere capacity watthour meter, the drum controller 18b is set in its appropriate position 5d, lid or 58d, In each of these positions, the full-load test of the appropriate watthour meter may be conducted as discussed with reference to 1.

Should it be desired to conduct a light load a test of a 5 ampere, 15 ampere or 50 ampere 'capacity watthour meter, the drum controller 18b ten revolutions of the test meter at full load, the standard meter indicates an error of 0.5% in each A still further problem is presented by the var-' iatlon in watthour constant 01 various watthour meters. For example. let it be assumed that three watthour meters are to be tested having rated full load current capacities of 5 amperes, 15 amperes and 50 amperes respectively. Let it be assumed further that the 5 ampere and 50 ampere watthour meters have basic watthour constants of 0.6 watthour. This means that one revolution of the armature of the 5 ampere watthour meter corresponds to a registration of .6 watthour. One revolution of the armature of the 50 ampere meter corresponds to a registration of 6 watthours.

Let it be assumed further, however, thatthe 15 ampere capacity watthour meter has a basic watthour constant of 0.5 watthour. This means that one revolution of the armature of the 15 ampere capacity watthour meter produces a registration of 1.5 watthours.

11' the standard watthour meter is designed to, have a constant basic watthour constant of 0.6,

' it follows that the armature of the standard watthour meter when conneced to test the '15 ampere capacity watthour meter rotates at a rate of rowatthour meter to be tested may be determined Q by suitable computations. For example, let it be assumed that the watthour meter to be tested under the conditions of the test has an armature rotation of r revolutions and a watthour constant of kn. Let it be assumed further tiiat the standard watthour meter under the same conditions has an armature rotation of R. revolutions and a watthour constant Kn. Under these conditions, the percent accuracy of the watthour meter unde test is represented by the formula IOOrk RKi In order to simplify the testing of watthour mehour meters having .the same basic watthour constants, such as 0.6 watthour, and having rated current capacities, respectively, of 1, 5, 15 and 50 amperes. The operation of the controller under these conditions is similar to that of the drum controller 16 oiFig.l. 4

For facilitating the testing of a 15 ampere capacity watthour meter having a different basic watthour constant,- such as 0.5 watthour, the

drum controller 160 is provided with the position l2*/ e which is designed to produce a full load operation oi the standard watthour meter when the standard watthour meter is supplied from the conductors 82 and 84 with a current of 12 amperes. This means that when 15 amperes of -words, 12% is equal to (0.5/0.6) x15.

As shown in Fig. 4, the windings lw to lllw are associated with the terminals lb to "lb of a first control unit 18c and'wlth terminals lc to 90 of a second control unit 800 in a manner somewhat analogous to that disclosed in Fig. 1. One of conductors 82 which supplies current to the windings is connected to one terminal of the coil lllw and the terminal lb. The remaining conductor 84 is connected to the terminal 90, a terminal i'lb associated'with the control unit 180, and a terminal I80 associated with .the control unit Me. In addition, the terminal 8c of the control unit 800 is connected to an additional terminal 19c.

For properly associating the contact segments of the control units, a tie conductor 220 is provided having its ends connected to contact segments which connect the terminal l'lb to the terminal I90 at the position l2/2e of the drum controller lie. The tie conductor 222 has its ends associated with contact segments for connecting the terminals "lb and I80 in the position le of the drum controller. Tie conductors 224 and 226 are associated with contact segments for establishing connections between terminals 9b and 80;

drum controller, and all of the terminals Ic to 90 inclusive, in the position 50c 01 the drum controller.

If it were desired to provide ranges corresponding to the positions is, e, l2 /2e and We only of the drum controller 180, it would be possible to employ a 50 ampere turn per currentpole energization of a standard watthour meter for each oi these ranges. However, since it is desired to and between 5!) and 4c in the first three positions le, 5e and Pic of the drum controller. Contact segments at the ends of the tie conductors 228, 230, 232 and 234 establish connections between the terminals 8b and 1c, between 3b and 20, between 2b and lo, and between 6b and 5c in the first four positions le, 5e, 15c and iz e of the drum controller. A tie conductor 236 has contact segments at its ends for establishing connections between the terminalsflb and 6c in thepositions le, 5e and I2 e of the drum controller. Finally,

a tie conductor 238 has contact segments for establishing a connection between the terminals band 3c ln the positions 5e and l 2 /2e of the drum controller. v

In addition, the control unit lie is provided with a contact segment 240 which engages the terminal I b'in the position 5c of the drum controller, the terminals lb, lb and lb in the position provide in addition thereto a range for testing 15 ampere capacity watthour meters. it is convenient to provide 45 ampere turns per current pole in some of the ranges. For example, in the position Ie the winding lflw alone is connected across the conductors 22 and 84 to-provide 45 ampere turns per current pole when one ampere flows therethrough. 9w are connected in series across the conductors 82 and 84 to provide 45 ampere turns per current pole when 5 amperes flow therethrough. In the position l5 e of the drum controller 15 amperes flow successively through the windings Iw, 4w and la: in parallel, the windings 2w, 5w and 810 in parallel, and the windings 31, 61c and 9w in parallel to'provide 45 ampere turns per current pole. a

In the position I2 /2e, l2 /2 amperes flow successively through the windings lw and 510 in parallel, the windings 2w and 6w in parallel, the

windings 320 and 1w in parallel and the windings 4w and 8w in parallel, to provide 50 ampere -urns per currentpole. In the final position, 50 amperes flow through the windings '"iw to 8w in parallel to provide 50 ampere turns. v p

Since the last two positions of the drum controller alone provide 50 ampere turns per current pole when rated current flows therethrough,

whereas the remaining positions provide 45 ampere turns per current pole, the cam H2 and associatedswitching mechanism again are employed to control the connections of the voltage windings I0, 12, I08 and H0. It is believed that the operation of the modification illustrated in Fig. 4 is clear from the discussion of the operation of the system illustrated in Fig. 1.

Although the invention has been described with reference to certain specific embodiments thereof, numerous modifications are possible. Therefore, the invention is to be restricted only by the appended claims as interpreted in view of the' prior art.

I claim as my invention: 1 I i. In a measuring device for measuring a function of a plurality of variable quantities and for providing the same response for each of a plurality or ranges of-a first one of said variable quantities, a measuring unit having first operating means and second operating means for en'ergization respectively by said first one and a second one of said variable quantities, said measuring unit including translating means responsive to the combined energizations of both of said operlie of the drum controller, the terminals lb and 5b in the position I2 Ae of the drum controller, and all of the terminals": to 9b inclusive, in the position We of the drum controller. Similarly, the control unit lillc has a contact segment 242 for engaging the terminal 90 in the position ie of the drum controller, the terminals 90, 3c and 6c in the position lie of the. drumcontroller, the

terminals ac and lo m the position me: a]: the

ating means, control means ioradjusting said first operating means to vary the energization of said first operating means by said first quantity and to adjust said measuring unit partially for the same response 01' said translating means to each of said ranges oi said first quantity, and control means for modifying theenergizatlon of said second ope ating means by said second quantity sufllciently to complete the adjustment of said measuring unit for each of said ranges of said first quantity; j 2. Ina measuring'device for measuring a'iunction of a plurality ofvariable quantities and Ior In the position So, the windings lw to providing the same response for each ot a plurality or ranges of a first one said variable quantities, a measuring unit having first operating means and second operating means-for energization respectively by said first one and a. second one of said variable quantities, said measuring unit including translating means responsive to the combined energizations of both or said operating means, control means for adjusting said first operating means to vary the energization of said first operating means by said first quantity and to adjust said measuring unit partiaily is: the same response of said translating means to each of said ranges of said first quantity, contrei means for modifying the energization of said second operating means by said second quantity suiilciently to complete the adjustment of said measuring unit for each of said ranges of said first quantity, and common means for operating or said control means.

3. Sins. measuring device for measuring a function of current and voltage in electrical circuits and for providing the same response for each of a plurality oi ranges of current, a measuring unit having first operating means and second operating means for energization respectively by current and voltage, said measuring unit including translating means responsive to the combined energizations of both oi. said operating means, control means for adjusting said first operating means to vary the energization of said first opmeans, and means eflective when said current windings are arranged to provide the lesser of said difierent numbers 0! ampere-turns for increasing the energizatlon of said voltage responsive operating means above the energization of said voltage responsive operating means for higher of said diflerent numbers of ampere-turns by an amount sufucing to provide the same response of said translating means for each of said ranges.

6. In a measuring device for measuring a function of the product of voltage and current in an eiectricai circuit and for providing the same response for of a plurality of ranges of current, operating means for said measuring device including a plurality of current windings, means' ranged to provide less ampere-turns for currents in oerta *"Etld ranges than for corresponding 29 of said ranges of current, a plucrating means by said first quantity and to adjust Y said measuring unit partially for the same response of said translating means to each of said ranges of current, and control means for modifying the energization 01' said second operating means by voltage sumciently to complete the adjustment of said measuring unit for each of said ranged to provide less ampere-turns for currents in certain of said ranges than for corresponding currents in other of said ranges of current, voltage operating means for said measuring device, said measuring device including translating means responsive to the combined energizations of said operating means, and means efiective when said current windings are ,arranged to provide said lesser ampere-turns for modifying the energization of said voltage operating means sufliciently to provide the same response of said translating means for each 01' said ranges.

5. In a measuring device for measuring a function of the product of voltage and current in an electrical circuit and for providing the same response for each of a plurality of ranges of current magnitudes, operating means for said measuring device including a plurality of current windings, means for increasing the number of eflective turns of said windings for the lesser of said ranges of current magnitudes, said windings being arranged to provide different numbers of ampere-turns for corresponding currents in said ranges which are intended to provide the same response of said measuring device, voltage responsive operating means for said measuring device, said measuring device including translating means responsive to the combined energizations of said operating pensive operating means for vice, said measuring device in- 3 means responsive to the comzons of said operating means, means effective when said current windingsare arranged to provide said lesser ampere-turns for energizing part only of said voltage responsive operating means in accordance with the voltage of the circuit to be measured, and means effective when said current windings are arranged to provide a greater number of ampere-turns for corresponding currents in other of said ranges for energizing all of said voltage responsive operating means, said voltage responsive operating means being proportioned to provide the same response 'of said translating means in. each of said ranges of current.

7. In a measuring device for measuring a function of the product of voltage and current in an electrical circuit and for providing the same response for each of a plurality of ranges of current magnitudes, means for operating said measuring device including a plurality of current windings, means for increasing the number of effective turns of said windings for the lesser of said ranges of current magnitudes, said windings being arranged to provide different numbers oi'ampere-turns for corresponding currents in said ranges which are intended to provide the same response of said measuring device, a plurality of voltage windings, said measuring device including translating means responsive to the combined energizations of said current and voltage windings, means connecting all of said voltage windmgs tor energization when said current windings are connected to provide a relatively small number of ampere-turns in. certain oi. said ranges of current, said last-named means including means connecting part only of said voltage windings for energization when: said current windings are connected to provide a relatively large number of ampere-turns in other of said ranges of current, said voltage windings being proportioned to provide the same response 01 said translating means to corresponding values or current in each of said ranges of current,

8. In a meter device for measuring electrical energy and for providing the same response for corresponding currents in each of a plurality of ranges of current magnitude, means for operating said meter device including a. plurality of cur-- rent windings, control means for varying the arrangement of said windings in accordance with the range of current magnitude to be measured, said windings providing a smaller number of ampere-turns for a current in a first one of said ranges than for a corresponding current in a second one of said ranges which is intended to produce the same response in said measuring device, voltage winding means associated with said current windings, said voltage winding means and said current windings cooperating when energized to operate said meter device, control means for increasing the voltage applied to said voltage-winding means in said first range sufliciently above that applied to said voltage winding means in said second range to provide similar responses of said meter device in said ranges for corresponding currents, and common means for operating said control means.

9. In a measuring device for measuring a function of the product of voltageand current in an electrical circuit and for providing the same response for each of a plurality of ranges of current, means for operating said measuring device including a plurality of current windings, means for energizing certain of said windings for each of said, ranges of current, said windings being arranged to provide less ampere-turns for'currents in certain of said ranges than for corresponding currents in other of said ranges of current, a plurality of voltage windings for said measuring device, translating means responsive to the energization of said windings, means selectively operable for connecting said voltage windings in series or in parallel for operation at either of two voltages, and means effective when said current windings are arranged to provide said lesser ampere-turns for increasing the effective energization of said measuring device by said voltage windings sufliciently to provide the same response of said translating means for each of said ranges.

10. In a meter for measuring a function of the product of voltage and current in an electrical circuit and for producing the same response for each of a plurality of ranges of current, a plurality of current windings, control means for arranging said current windings in different circuit combinations each designed for energization .in a separate one of a plurality of ranges wherein the rated load currents are respectively, 0.5, 1.5, 5, 15 and 50 amperes, and voltage-responsive operating means for said meter, translating means responsive to the combined energizations of said current windings and said voltage-responsive operating means, said voltage-responsive operating means cooperating with said control means and current windings to provide the same response of said translating means when the applied voltage is constant and the current supplied to said meter has any of the values 0.5, 1.5, 5, 15 and 50 amperes in the corresponding ranges thereof.

11. In a meter for measuring a function of the products of voltage and current in an electrical circuit and for producing the same response for each of a plurality of ranges of current, operating means for said meter including a plurality of current windings, control means for arranging said current windings in diflerent circuit.

combinations each designed for energization in a separate one of a pluralityof ranges wherein the rated load currents are respectively, 5, 12 and 50 amperes, and voltage energizing means for said meter, said voltage energizing means cooperating with said control means and current windings to provide the same response of said meter when the applied voltage is constant and the current supplied to said meter has any of the values 5, 12 and amperes.

12. In a measuring device for measuring a function of the product of voltage and current in an electrical circuit and for providing the same response for each of a plurality of ranges of current, a magnetic structure having an air gap, current winding means associated with said magnetic structure, said current winding means being efiective when energized for directing a current magnetic flux through said air gap, voltage winding means associated with said magnetic structure, said voltage winding means being effective when energized for directing a voltage magnetic flux through said air gap, armature means disposed in said air gap for rotation relative to said magnetic structure, said magnetic fluxes coacting to. apply to said armature means a torque acting to rotate said armature relative to said magnetic structure, said current winding means comprising a plurality of windings, connecting means operable for connecting said windings in various circuit relationships, each of said circuit relationships being designed for operation over a predetermined separate current range having a rated current differing from that of other of. said current ranges, said circuit relationships when enerrent, a magnetic structure having an air gap,

current winding means associated with said magnetic structure, said. current winding means being efiective when energized for directing a current magnetic flux through said air gap, voltage winding means associated with said magnetic structure, said voltage winding means being effective when; energized for directing a voltage magnetic flux through said air gap, armature means disposed in said air gap for rotation relative to said magnetic structure, said magnetic fluxes coacting to apply to said armature means a torque acting to rotate said armature relative to said magnetic structure, said current winding meanscomprising a plurality of windings, first connecting means operable for connecting said windings in various circuit relationships, each of said circuit relationships being designed for operation over a predetermined separate current range having a rated current differing from that of other of said current ranges, said circuit relationships when energized by their respective rated currentsproducing different values of said current magnetic flux, said voltage winding means comprising first winding means effective when energized from a voltage source for producing a first voltage magnetic flux which cooperates with a first one of said different values of current magnetic flux to apply a predetermined torque to said determined torque to said armature element, and second connecting means selectively operable for connecting said first winding means alone or for connecting both said first winding means and said second winding means for energization from a voltage source. i I

14. In a measuring device for measuring a function of the product of voltage and current in an electrical circuit and for providing the same response for each of a plurality of ranges of current, a magnetic structure having an air gap, current winding means associated with said magnetic structure, said current winding means being effective when energized for directing a current magnetic flux through said air gap,'voltage winding means associated with said magnetic structure, said voltage winding means being effective when energized for directing a voltage magnetic flux through said air gap, armature means disposed in said air gap for rotation relative to said magnetic structure, said magnetic fluxes coacting to apply to said armature means a torque acting to rotate said armature relative to said magnetic structure, said current winding means comprising a plurality of windings, first connecting means operable for connecting said windings in various circuit relationships, each of said circuit relationships being designed for operation over a predetermined separate current range having a rated current differing from that of other of said current ranges, said circuit relationships when energized by their respective rated currents producing different values of said current magnetic flux, said voltage winding means comprising first winding means effective, when energized from a voltage source for producing a first voltage magnetic flux which cooperates with a first one of said different values of current magnetic fiux to apply a predetermined torque to said armature element, second winding means efiective when energized in conjunction with said first winding means from said voltage source for producing a second voltage magnetic flux which cooperates with a second one of said different values of current magnetic flux to apply said predetermined torque to said armature element, second connecting means selectively operable for connecting said first winding means alone or for connecting both said first winding means and said second winding means for energization from a voltage source, and common control means for operating both said first and said second connecting means from conditions suitable for producing said first voltage magnetic flux and said first one of said difierent values of current magnetic fiux to conditions suitcurrent winding means associated with said magnetic structure, said current winding means being effective when energized for directing a current magnetic flux through said air gap, voltage winding means associated with said magnetic structure, said voltage winding means being eiiective when energized for directing a voltage magnetic flux through said air gap, armature means disposed in said air gap for rotation relative to said magnetic structure, said magnetic fluxe coacting to apply to said armature means a torque acting to rotate said armature relative to said magnetic structure, said current winding means comprising a plurality of windings, connecting means operable for connecting said windings in various circuit relationships.

each of saidcircuit relationships being designed for operation over a predetermined separate current range having a rated current differing from that of other of said current ranges, said circuit relationships when energized by their respective rated currents producing different values of said current magnetic fiux, transforming means for controlling the voltage applied to said voltage winding means from a source of voltage, and adjusting means associated with said transforming means for modifying the voltage applied to said voltage Winding from the source of voltage to produce a different value of voltage magnetic fiux for each of said values of current magnetic flux, said values of voltage magnetic flux being proportioned to apply the same predetermined torque to said armature means for all of said values of current magnetic 16.-In a measuring device for measuring a function of the product of voltage and current in an electrical circuit and for. providing the same response for each of a plurality of ranges of current, a magnetic structure having an air gap, current winding means associated with said magnetic structure, said current winding means being effective when energized for directing a current magnetic flux through said air gap, voltage winding means associated with said magnetic structure, said voltage winding means being effective when energized for directing a voltage magnetic fiux through'said air gap, armature means disposed in said air gap for rotation relative to said magnetic structure, said magnetic fluxes coacting to apply to said armature means a torque acting to rotate said armature relative controlling the voltage applied to said voltage winding means from a source of voltage, adjusting means associated with said transforming means for modifying the voltage applied to said voltage winding from the source of voltage to produce a different value of voltagemagnetic flux for each of said values of current magnetic flux, said valuesof voltage magneticfiux being proportioned to apply the same predetermined torque to said armature means for all of said values of current magnetic flux, and common-,

control means for said connecting means and said adjusting means, said control means operating said connecting means and said adjusting means simultaneously to maintain said predetermined torque for all of said values 01' current magnetic flux.

AMBROSE J. PETZINGER. 

